DE2832504C3 - Use of mixtures of styrene polymers for the production of flexible drip chamber bases for transmission devices - Google Patents

Abstract

1. Use of polystyrene polymers for the production of drip chambers for transfusion apparatus, the upper part of the drip chamber consisting of polystyrene homopolymers or copolymers, characterized in that a mixture or alloy of a) polystyrene homopolymers or copolymers, with b) thermoplastic rubbers based on styrene-butadiene-styrene or styrene-isoprene-styrene block polymers are used for producing the flexible lower part of the drip chamber.

Description

a) styrene homo- or copolymers with

b) thermoplastic rubbers based on styrene-butadiene-styrene or styrene-isoprene-styrene block polymers

is used.

The invention relates to the use of mixtures containing styrene copolymers for production transparent, flexible drip chamber lower parts that can be sterilized with high-energy radiation in higher doses for transmission devices.

For the transfer of blood, blood components, infusion solutions and plasma expanders from one Containers in a receiver commonly used transmission devices consist, a general according to the usual and accepted construction scheme, from the piercing part designed as a hollow mandrel for piercing into the liquid container, a drip chamber with a drip tube to assess the set drop sequence, a flexible hose suitable length and one for making a line connection, e.g. B. to a catheter, serving Cone connection. A liquid regulator installed in the conduit or changes in cross-section that can be achieved through external influences are used to control the flow rate. Made of plastics, intended for single use Transmission devices of the aforementioned type are standardized in DIN standards 58 360 and 58 362.

The individual embodiments of the drip chamber can be very different. So are Drip chambers known, which are made of a flexible transparent plastic tube, for. B. a pipe made of plasticized polyvinyl chloride and processed by high-frequency welding and by the type of tubular starting maieria in one piece, so are made in one piece. Another shape is composed of two molded parts, the molded part, the piercing part and part of the cylindrical chamber, the other part the remaining part of the chamber and a tubular extension for fastening was the flexible hose "included.

Both parts can be joined to the final drip chamber by joining methods such as gluing, welding, form-fitting fit together airtight.

Depending on the selection of the plastics that can be used, one of the connection methods mentioned can be used, e.g. B. one is used for the connection of polyamide parts

len or polystyrene parts gluing or welding processes can apply while mechanical joining for those by gluing or welding not interconnectable plastics is to be provided. A much used drip chamber of this last type is a combination of a polystyrene drip chamber upper part and a polypropylene drip chamber lower part.

This material arrangement, however, has serious disadvantages, which can only be achieved by constructive auxiliary measures Can be overcome to make a safe to use and for a patient who has a Infusion or transfusion received, safe transmission device to arrive. One of those relief measures, I 'around the top and bottom of the drip chamber and to hold them together airtight when in use consists in removing the circular junction of the surrounds both parts on the outside with a holding mg that z. B. can be molded by the known injection molding process on the drip chamber.

With the appropriate design of anchoring elements that are attached to the molded ring in Interaction occurs, a sufficiently good tightness and mechanically rigid stability of the nested parts reached. If the plastic forming the retaining ring is selected so that it is with compatible with the underlying drip chamber material, d. H. is weldable, is through a at Injection of the plasticized plastic compound onto the drip chamber resulting in a welded joint excellent strength achieved between the drip chamber parts, while with incompatible and therefore, non-weldable components only result in mechanical cohesion.

Another requirement for modern drip chambers composed of two parts is that that their lower parts must be flexible to a certain extent. Must be used during fluid transfer a drip chamber can be partially filled with liquid in order to be able to act as an air trap. The filling itself is accomplished in a simple manner that one on the flexible wall pressure movements, z. B. by squeezing it with your fingers and let air out of the air through this pumping process Drip chamber pushes out and liquid located above the drip chamber in the infusion solution container can flow in.

Among the methods commonly used for the sterilization of plastic disposable devices for medicine, such as sterilization with ethylene-oud or sterilization with high-energy radiation, preference should be given to the latter method t!: R, as it can be used in the interior of elongated structural elements, e.g. B. Hoses. Sterility better guaranteed than the Äthylenoxidsterilisaiion and still does not leave any toxic ethylene oxide gas residues or toxic by-products resulting therefrom. However, some plastics, including z. B. Polypropylene, no longer stable at the required - ^b0 radiation doses of 3.5 ± 10% Mrad and are molecularly degraded under the action of radiation, which corresponds to an embrittlement of the material. Toughness and thus functional reliability are only guaranteed to a limited extent under these treatment conditions.

Finally, for reasons of product safety, it is necessary that the predominantly plasticized Polyvinyl chloride made hose of a transmission

The supply device is connected to the hose attachment of the drip chamber with sufficient tensile strength. With soft PVC Castable plastics do not present any difficulties in achieving a tensile strength of 20-30 N.

It can be seen that these values for poorly bonded material combinations such as polyamide and Soft PVC cannot be achieved and are no longer possible at all with polypropylene and soft PVC. in the DE-GM 72 13 189 is therefore a hose attachment that can be combined with solvents or adhesive solutions with a soft PVC hose in one Drip chamber with polypropylene base described. However, this procedure is cumbersome, material and expensive.

From DE-GM 77 27 564 a drip chamber connection in infusion and transfusion devices between the drip chamber upper part and the drip chamber lower part is known, the parts with a circumferential compressed flanged collar are connected to one another. Certain materials for the drip chamber parts are not specified.

DE-AS 16 20 851 discloses mixtures of styrene polymers with styrene-butadiene-styrene polymers and the use of the same for numerous molded bodies, such as shoe soles, among other things. Sporting goods, extruded profiles and pipes known. From column 3, lines 53 to 62 it can be seen that for For many purposes, finely divided fillers have to be used as important constituents. In the Examples 1 and 2 mention mixtures which are said to be particularly useful for shoe soles. the Other examples demonstrate property values of the polymer blends without any further information, apart from the Raw production, to be gelxn for use.

The DE-AS 16 20 851 can not entne men that the polymers mentioned there in any way for the production of flexible and above all Transparent parts for medical devices can be used, especially because of the further Requirements for medical devices (sterilisability by means of ethylene oxide or high-energy radiation, Weldability) still require special material concepts.

This results in the task, for the drip chamber consisting of the upper and lower part, according to the functional and manufacturing criteria to use a material that optimally meets the following requirements will.

1. Transparency for checking the drip chamber filling and assessment of the drop sequence as a measure of the Flow rate.

2. Flexibility and resilience of the drip chamber lower part for partial filling of the Lower part by pressing together.

3. Resistance to high-energy radiation in the range from 3.5 Mrad.

4. Integrated arrangement of the drip chamber lower part and hose attachment for gluing a conventional one Soft PV (hose * with solvents or adhesive solutions.

5. With regard to the weldability of mutually compatible plastic materials for the drip chamber upper part and lower part to either one liquid and airtight joint using known joining processes such as ultrasonic welding, heat pulse welding, friction welding, Mirror welding etc. or by overmoulding the assembled drip chamber parts with to achieve a plastic that is compatible in the same way.

6, Integrated arrangement of the top part of the drip chamber and the piercing part, which is suitable for perforating the closures of infusion solution containers and therefore must have sufficient hardness and rigidity.

The invention relates to the use of styrene polymers for the production of drip chambers for transmission devices, the upper part of the Drip chamber consists of styrene homo- or copolymers, characterized in that for production

of the flexible lower part of the drip chamber a mixture of

a) styrene homo- or copolymers with

b) thermoplastic rubbers based on styrene-butadiene-styrene or styrene-isoprene-styrene

rol block polymers

is used. In accordance with the above requirement profile,

the partially flexible drip chambers made of polystyrene, namely the top part of the drip chamber a styrene homo- or -eooolymerisat with high Rigidity and hardness that meet the requirements of U 3 " 5. and 6. corresponds to where suitable polymers are Normal polystyrene (homopolymers), copolymers based on styrene-acrylonitrile (SAN), acrylonitrile-butadiene-styrene (ABS), impact-modified polystyrene based on styrene-butadiene (SB), methyl methacrylate-butadiene-styrene (MBS) and methyl acrylate-styrene-acrylonitrile (ASA) and the modifications of these systems known to those skilled in the art, and the flexible lower drip chamber part made from a blend of 1. styrene homo- or copolymer and 2. thermoplastic rubber based on styrene-butadiene-styrene (SBS) or S'yrol-Iso pren-styrene (SIS) block copolymers that meet the requirements changes I to 6 corresponds. For the production of the blend suitable polymers according to 1. are copolymers Based on styrene-butadiene (SB) and methacrylate-butadiene-styrene (MBS). In principle, the with are suitable for this

+5 thermoplastic rubbers based on styrene-butadiene-styrene or styrene-isoprene-styrene miscible styrene homo- and copolymers whose refractive indices π are so compatible that largely transparent mixtures with a high degree of trans mission in the visible ren light result.

Novel styrene-budadiene copolymers draw as well as the long-known styrene homopolymers and some styrene copolymers based on them Styrene acrylonitrile or methacrylic acid ester butadiene

5 * styrene are characterized by extensive transparency and offer In addition, significantly improved toughness and impact resistance, which is why they are more flexible to manufacture and injection molded parts that are more resistant to mechanical stress are advantageously used

w can be. Despite the higher flexibility compared to conventional styrene homopolymers in some applications this is not sufficient to achieve the desired function of a flexible drip chamber ensure and therefore be thermoplastic

· 'Rubbers based on styrene-butadiene-styrene or Styrene-isoprene-styrene used according to the invention in order for sufficient flexibility with constant To ensure transparency.

Thermoplastic rubbers are block copolymers with the schematic sequence

SSSSS BBBBBBBBBBSSSSS
(S = styrene molecule, B = butadiene molecule).

Triblock copolymers or radial block copolymers of the S-B-S type, in which the outer blocks S of the polymer chain identical polystyrene segments with vitreous, thermoplastic Character are. The rubber-like center block B is elastic and consists of polybutadiene or polyisoprene. The polystyrene phase is separated at a certain percentage and consists of small ones Aggregates that are embedded in the continuous polybutadiene or polyisoprene matrix and are so small that that there is no scattering of visible light, which means transparency of the polymer.

It has been found that mixtures (blends) of styrene copolymers and thermoplastic rubber are formed based on styrene-butadiene-styrene or styrene-isoprene-styrene excellent for the production of flexible, transparent, bondable and weldable Have the drip chamber bases used if the two components are mixed in suitable proportions mixed, homogenized and processed into molded parts by injection molding.

Preferably used as styrene copolymers or these corresponding polymer mixtures impact-resistant, transparent styrene-butadiene copolymers or Methacrylate-butadiene-styrene polymer mixtures are used.

Suitable moldings are obtained if from 30-90% of a styrene copolymer or a corresponding one Polymer mixture, preferably 60-80%, with 70-10%, preferably 40-20%, of a thermoplastic rubber based on styrene-butadiene (isoprene) -styrene a compound is produced and processed by injection molding.

Examples of suitable blends are given below:

example 1

60 percent by weight of a polymer mixture based on methacrylate-butadiene-styrene (MBS) in granulate form are with 40 percent by weight of a particulate or granulated thermoplastic styrene-butadiene-styrene rubber in a mixer,

_{| 0} z. B. tumble mixer, well mixed and melted homogeneously in a mixing extruder or internal mixer, extruded and granulated. The granulate obtained is formed into a lower part of the drip chamber in the injection molding process and the part thus obtained is connected to an upper part of the drip chamber by ultrasonic welding. The drip chamber incorporated in a transmission device for infusion solutions is fully functional and meets the requirements for tightness, transparency, flexibility and material quality

resistance to ethylene oxide and gamma sterilization.

Example 2

75 percent by weight of a transparent styrene-butadiene copolymer in granulate form with 25 percent by weight of a particulate or granulate thermoplastic styrene-butadiene-styrene rubber mixed in a mixer and in one Mixing extruder homogeneously melted, extruded and granulated. Get it like this: Granules are for them

J ₀ suitable for injection molding processing and drip chamber lower parts are made from it with an appropriate injection molding tool. Combined with an upper part of the drip chamber, both parts are connected to one another. The received drip chamber as part

of a transmission device fully complies with the requirements to be placed on such a part as Leak-tightness, transparency, flexibility, gluability and durability during sterilization with high-energy Radiation or with ethylene oxide.

Claims (1)

Claim: Use of styrene polymers for the production of drip chambers for transmission devices, the upper part of the drip chamber from Styrene homopolymers or copolymers, characterized in that for production of the flexible lower part of the drip chamber a mixture of